Systems and methods for providing a stationary umbrella with integrated hydration, automation, and entertainment features

ABSTRACT

A system for providing a weather, hydration, and entertainment shelter, the system comprising: an umbrella supported by a base, an insulated cabinet attached to the base, the insulated cabinet having a door, and defining a fluid-reservoir receiving means; a fluid delivery system comprising a reservoir, a pump, a spigot disposed on an upper portion of the insulated cabinet, and fluid tubing; and a control panel disposed on the insulated cabinet and having a user-interface input, the control panel configured to activate a fluid-conveyance means to convey a fluid from the reservoir, via the fluid tubing, to the spigot in response to receiving a fluid-dispense request at the user-interface input.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No. 62/164,344, entitled “SYSTEMS AND METHODS FOR PROVIDING A STATIONARY UMBRELLA WITH INTEGRATED HYDRATION, AUTOMATION, AND ENTERTAINMENT FEATURES”, filed May 20, 2015, reference of which is hereby incorporated in its entirety.

BACKGROUND

Umbrellas of various designs are well-known for protecting people from rain and sun. A hand-held umbrella typically protects one person from the elements, but may only be large enough to protect a single user. Larger umbrellas are commonly used on decks, patios, and around pools. These larger umbrellas are mounted on a pole and typically include a large weight, or extend through a table so as to be supported at the base and at a point on the pole above the base to provide additional support for an umbrella in the presence of wind. Large umbrellas can require a significant amount of weight at the base and are normally set up and maintained in one place and are not intended to be portable for traveling with a user.

SUMMARY

In accordance with an embodiment, a shelter includes an umbrella supported by a base, an insulated cabinet attached to the base. The insulated cabinet includes a door and defining a fluid-reservoir receiving means. The shelter further includes a fluid delivery system having a reservoir, a pump, a spigot disposed on an upper portion of the insulated cabinet, and fluid tubing; and a control panel disposed on the insulated cabinet and having a user-interface input. The control panel is configured to activate a fluid-conveyance means to convey a fluid from the reservoir, via the fluid tubing, to the spigot in response to receiving a fluid-dispense request at the user-interface input.

In one embodiment, the control panel is further configured to provide an electrical charge, via the electronic device charging station to an electronic device, in response to a signal from an identity-verification device. In another embodiment, the fluid-reservoir receiving means includes a ramp configured to receive a reservoir cart loaded with a fluid reservoir.

BRIEF DESCRIPTION OF THE DRAWINGS

A more detailed understanding may be had from the following description, presented by way of example in conjunction with the accompanying drawings, brief descriptions of which are listed below. This application describes various aspects and embodiments of an automated weather, hydration, and entertainment shelter, or “shelter” for brevity.

FIG. 1A depicts an overview of a shelter, in accordance with an embodiment.

FIG. 1B depicts a view of an insulated cabinet, in accordance with an embodiment.

FIG. 2A depicts a ramp of an insulated cabinet, in accordance with an embodiment.

FIG. 2B depicts a fluid and electrical connector pair, in accordance with an embodiment.

FIG. 2C depicts a fluid and electrical connector pair, in accordance with an embodiment.

FIG. 3 depicts a shelter including a solar panel, in accordance with an embodiment.

FIG. 4 depicts a schematic functional block diagram of a computer processing system, in accordance with an embodiment.

DETAILED DESCRIPTION

In accordance with an embodiment, a shelter includes: an umbrella supported by a base, an insulated cabinet attached to the base, the insulated cabinet having a door, and defining a fluid-reservoir receiving means; a fluid delivery system comprising a reservoir, a pump, a spigot disposed on an upper portion of the insulated cabinet, and fluid tubing; and a control panel disposed on the insulated cabinet and having a user-interface input, the control panel configured to activate a fluid-conveyance means to convey a fluid from the reservoir, via the fluid tubing, to the spigot in response to receiving a fluid-dispense request at the user-interface input.

In accordance with an embodiment, a stationary shelter is integrated with electronics for hydration, automation, and entertainment features. In at least one embodiment, a stationary umbrella or shade canopy with integrated hydration, automation and entertainment features has batteries, lights integrated into the umbrella or shade canopy, one or more liquid reservoirs contained within an insulated cabinet or housing, one or more pumps, systems to connect the liquid reservoirs to a spigot or serving spout, an optional means of restricting access to users or requiring pre-payment or verification by a user before dispensing a beverage or authorizing use of the electronics within the device, a water connection for receiving liquid from an external water source for an optional fan and spray mist attachment, a motor or gear in communication with a system for automatically opening and closing the canopy based on pre-determined settings, a battery, and a control module.

In one embodiment, the insulated cabinet further comprises a ramp configured to receive a reservoir cart.

In one embodiment, the shelter further includes an electrical power distribution system configured to supply electrical power to the control panel. In one such embodiment, the electrical power distribution system comprises a rechargeable battery. In one such embodiment, the rechargeable battery is disposed inside the insulated cabinet.

In one embodiment, the electrical power distribution system further comprises a solar panel and a battery; and the electrical power distribution system is further configured to convey electrical power from the solar panel to either one or both of the control panel and the battery. In one such embodiment, the solar panel further comprises an electric eye configured to detect a position of a light source; the solar panel is configured to reposition in response to an input from the electric eye; and the input is based on the detected light source position. In one such embodiment, repositioning the solar panel comprises one or both of rotating and tilting.

In accordance with an embodiment, the control panel further comprises an electronic device charging station. In one such embodiment, the control panel is further configured to provide an electrical charge, via the charging station to an electronic device, in response to a signal from an identity-verification device.

In accordance with an embodiment, the shelter further includes lights affixed to the underside of a canopy of the umbrella, and the electrical power distribution system is further configured to supply electrical power to the lights.

In accordance with an embodiment, the fluid delivery system further includes a flow meter configured to detect a volume of fluid dispensed and communicate the detected volume to the control panel.

In accordance with an embodiment, the fluid delivery system further includes a plurality of reservoirs, and the spigot is further configured to dispense a liquid from a selected one of the plurality of reservoirs.

In accordance with an embodiment, the shelter further includes a beverage opener. In one such embodiment, the beverage opener is selected from a group consisting of a beer bottle opener and a wine bottle opener.

In accordance with an embodiment, the shelter further includes a thermo-electric cooling element configured to transfer heat from a liquid contained in the reservoir.

In accordance with an embodiment, the umbrella is configured to be operated by an electric motor. In one such embodiment, the umbrella is further configured to be operated to a closed position in response to an infra-red detector not detecting a person under the umbrella.

In accordance with an embodiment, the shelter further includes an entertainment system comprising an audio speaker configured to play sound. In one such embodiment, the shelter is further configured to wirelessly receive data and the speaker is further configured to play sound based on the wireless received data.

In accordance with an embodiment, a power supply acts as a base of an umbrella associated with the shelter. In such an embodiment, the base further comprises an insulated cabinet and integrated electronics. The integrated electronics may be configured to provide lighting, music, charging services and the like. The lighting is configured to illuminate the area under the shelter and may be further configured to provide customized illumination, to include changing color schemes and light levels. The lights may change configurations, such as brightness, color, and the like, based on receiving an input via a fixed or detachable remote, smartphone, or the like.

In accordance with an embodiment, the shelter comprises a computer configured to communicate with a network. The communications comprising sending and receiving status updates, fluid levels, fluid temperatures, weather conditions, operating instructions, music, sound announcements, and the like.

In accordance with an embodiment, the shelter is further configured with a solar charging device, the solar charging device configured to charge the batteries of the shelter. The solar charging device may further include a mounting bracket for holding the solar panel, and including an axial support whose angle may be adjusted according to the latitude of the location where the device is to be used such that the mounting bracket can pivot and generally track the movement of the sun. The bracket may also include a directional light sensor that is used to provide a feedback signal to control an actuator configured to automatically reposition to track a light source.

In accordance with an embodiment, reservoirs and tubing in the shelter may be configured to dispense a fluid as a fluid-conveyance means. In such an embodiment, the shelter may be configured to dispense at least one liquid to at least one spigot associated with the shelter. The spigot is located in a convenient location on the shelter. The convenient location may be a surface of the insulated cabinet, an upper portion of the insulated cabinet, the support post for the umbrella, or the like. A pump, either electric or manual, is used to pressurize the liquid. Liquid stored in the reservoir is dispensed through the spigot in response to a switch being activated. The flow path may be established by operation of valves, pumps, or a combination of valves and pumps to provide a flow path for the fluid and a pressure to move the fluid. In accordance with an embodiment, a plurality of switches may be present, each configured to dispense liquid from a different reservoir through the spigot. The shelter may further be configured to dispense fluid from a reservoir, provide charging services, play music, operate a climate control system, and perform other similar functions after verifying an identity of a user.

A user's identity may be determined via a smartphone application, an NFC card/chip, an electromagnetic key card, and so on.

The tubing system may comprise a flow sensor configured to track the fluid dispensed. The amount of fluid dispensed, as determined by the flow meter, may be sent to a communication network to determine when refills are required at the shelter or to charge a determined user for dispensing the amount of fluid. The amount of fluid dispensed may also be associated with an identity of a person requesting the fluid to be dispensed. In such an embodiment, the amount of fluid dispensed and user identification data is transmitted to a remote server. The remote server may use the received data to determine proper hydration of a user associated with the user identification, log the amount of fluid dispensed by each user, and the like.

In accordance with an embodiment, the shelter may be configured to receive the reservoirs via a cart. In such an embodiment, the reservoirs are stored in the insulated container to connect to tubing configured to convey liquid to the spigot. The insulated container may be configured with a ramp, the ramp configured to allow the cart to roll up and deliver reservoirs to the insulated container.

In accordance with an embodiment, a shelter may be further configured to provide climate control. The climate control may comprise fans, misters, and a combination of fans and misters. The misters are configured to receive water from an external source or a reservoir stored in the insulated container via a tubing system. The water is conveyed to the mister either through pressure from the external source or a pump associated with the shelter.

In accordance with an embodiment, the shelter may be configured with mechanized deployment and retraction of an umbrella associated with the shelter. In such an embodiment, the mechanized deployment and retraction may be in response to a received signal indicating deployment, a set schedule, or retraction or in response to detecting adverse weather conditions.

The reservoirs may be configured with fluid level and fluid temperature detectors. The detectors configured to detect a fluid level and a temperature, respectively, of the reservoirs and communicate the detected levels and temperature to a computer for communication with a network. The levels may be continuously communicated, communicated per a set schedule, or only when a threshold level is crossed.

In accordance with an embodiment the shelter is configured to customize illumination for ease of identification of a user's umbrella for purposes of meeting in a crowded location such as a beach, concert, or festival where it is not easy to coordinate or distinguish or identify a meeting spot or pick out a base camp amongst the crowd.

In accordance with an embodiment the shelter further comprises a power inverter attached or otherwise in communication with the batteries housed within the umbrella or one of the insulated containers capable of transforming direct current to alternating current for charging a user's electronic devices or powering optional attachments, such as a blender, power tools, an external speaker, and the like.

In accordance with an embodiment the shelter further comprises a manual, battery powered, or electronic compressor for inflating the small inner tube or pressurizing the water tank for operating the optional mist/fan attachment.

In at least one embodiment, a first tubing system mechanically interconnects the liquid, a reservoir, a pump, and a spigot.

In at least one embodiment, a second tubing system mechanically interconnects to a second reservoir, a pump, and a spigot.

In at least one embodiment, the control module includes a mode selector control switch and an intensity selector control switch for the LED lights on the canopy frames.

In at least one embodiment, the liquid contained within the reservoir is water.

In at least one embodiment, the liquid is another beverage, such as alcohol, juice, soda or a mixture of the two.

In at least one embodiment, the reservoir is insulated. In at least one such embodiment, the reservoir further includes a fill cap or opening lid, a drain tubing, and the insulated liquid reservoir is a source of potable liquid for hydration.

In at least one embodiment, the first reservoir tubing system includes quick-release interconnects so the internally housed reservoirs or containers can be quickly disconnected by the user for cleaning

In at least one embodiment, the second tubing system provides a flow path for potable liquid from the liquid reservoir to the first flow-control valve, the potable water to be used for hydration.

In at least one embodiment, the battery comprises a rechargeable battery. In at least one such embodiment, the battery receives an electrical charge when the device is connected to an external power supply.

In at least one embodiment, the battery comprises a replaceable battery.

In at least one embodiment, the internal battery is a rechargeable battery.

In at least one embodiment, the internal battery recharges when an external power supply is connected.

In at least one embodiment, the internal battery is a replaceable battery.

In at least one embodiment, the internal battery is able to be charged by a generator form a combustion source.

In at least one embodiment, a shelter includes an umbrella with lights integrated into the canopy, two liquid reservoirs, a pump, first and second tubing systems to connect the liquid reservoirs to a spigot or serving spout, a water connection for receiving liquid from an external water source, a battery, and a control module. In some embodiments, the insulated cabinet is configured to receive a plurality of reservoirs.

FIG. 1A depicts an overview of a shelter, in accordance with an embodiment. In particular, FIG. 1A depicts the shelter 100. The shelter 100 includes an umbrella 102 supported by a base 104, a reservoir 106, an insulated cabinet 110 attached to the base 104, the insulated cabinet having a door and defining a fluid-reservoir receiving means, a control panel 112 disposed on the insulated cabinet 110 and having a user-interface input, a spigot 114 disposed on an upper portion of the insulated cabinet 110, and an upright support pole 116. The fluid delivery system includes the reservoir 106, a pump, the spigot 114, and fluid tubing. The insulated cabinet 110 defines a fluid-reservoir receiving means. The fluid delivery system is configured to convey a fluid from the reservoir 106, via the fluid tubing, to the spigot 114 on the upper portion of the insulated cabinet 110 in response to receiving a fluid-dispense request from the control panel.

In the FIG. 1A, the umbrella 102 is depicted in an open, or extended, position. The insulated cabinet 110 is attached to the base 104 which supports the umbrella and is configured to house the reservoir 106, defining a fluid-reservoir receiving means. The control panel 112 is disposed on the upper portion of the insulated cabinet 110, and includes various control elements to operate the shelter. The control panel 112 may include a user interface having a user-interface input and a processor configured to execute programmable instructions stored in system memory. The user interface may be any number of user interfaces to include a touch screen, buttons, light emitting diodes, and the like. The spigot 114 includes any type of outlet for fluid to be dispensed from. The user interface is able to receive a fluid-dispense request from a user indicating the user desires to dispense a fluid. In response to receiving the fluid-dispense request at the user-interface input, the control panel activates the fluid-conveyance means.

In accordance with an embodiment, the base 104 of the umbrella 102 is attached to the insulated cabinet 110. The insulated cabinet 110 serves as an anchor, or counterweight, to support the weight of the umbrella. In some embodiments, the umbrella is cantilevered out from an upright support pole. As depicted in FIG. 1A, the umbrella 102 extends to the right of the upright support pole 116 and the insulated cabinet 110 is on the left, or opposing, side of the upright support pole 116. The placement of the insulated cabinet 110 on an opposing side of the upright support pole 116 as the umbrella 102 offsets the torque of the cantilevered umbrella.

In some embodiments, the fluid-conveyance means includes the fluid delivery system having valves in line with the fluid tubing to restrict or permit flow from the reservoir to the spigot. The valves may be solenoid valves configured to open and close in response to signals from the control panel.

In some embodiments, the shelter includes a pump to convey the liquid from the reservoir to the spigot. The pump may be any number of pumps suitable to convey the liquid from the reservoir to the spigot as a means of fluid-conveyance. Some example pumps include an inline pump and a pump configured to pressurize an air space inside the reservoir. The inline pump may be a centrifugal pump, a positive displacement pump, or the like.

The pump may also pressurize an air space inside the reservoir to convey the liquid from the reservoir to the spigot. In such an embodiment, the pump compresses air from the atmosphere and outputs the compressed air to the reservoir through a pressurizing connection. In another such embodiment, the reservoir includes a collapsible portion that is mechanically deformed or compressed resulting in an increased pressure in the air space internal to the reservoir. When the mechanical pressure is removed from the reservoir, the collapsible portion of the reservoir expands as air is permitted to reenter the reservoir through a check valve.

In some embodiments, the means of fluid-conveyance includes the fluid delivery system being configured to convey a fluid from the reservoir, via the fluid tubing, to the spigot in response to receiving a fluid-dispense request from the control panel. The fluid-dispense request originates from the control panel and serves to activate the flow path of the fluid from the reservoir to the spigot. The activation of the flow path may comprise energizing, or turning on, the pump. The activated pump applies a pressure, either directly or indirectly, to the fluid in the reservoir to move the fluid from the reservoir, through the fluid tubing and to the spigot. The fluid tubing may also have valves in line that are required to be repositioned to activate the flow path. The valves may be solenoid operated valves that receive electrical signals from the control panel to reposition to activate or terminate the flow path.

FIG. 1B depicts a view of an insulated cabinet, in accordance with an embodiment. In particular, FIG. 1B depicts a view of the insulated cabinet 110. The insulated cabinet 110 defines a fluid-reservoir receiving means and includes the control panel 112 and the spigot 114. The reservoir 106 is connected to the spigot 114 via fluid tubing.

FIG. 2A depicts a ramp of an insulated cabinet, in accordance with an embodiment. In particular, FIG. 2A depicts a portion of the shelter 200. The shelter 200 includes the components of the shelter 100, and may also include a ramp 202. The ramp is a portion of the fluid-reservoir receiving means. The ramp 202 is configured to permit a reservoir cart 204 to roll up into the insulated cabinet 110. The ramp 202 may be a portion of the insulated cabinet 110 and fold down when positioned to receive the reservoir cart 204.

FIG. 2B depicts a reservoir cart, in accordance with an embodiment. In particular, FIG. 2B depicts the reservoir cart 204. The reservoir-cart may be a portion of the fluid-reservoir receiving means. The reservoir cart 204 includes the reservoirs 106. In some embodiments, the reservoir cart further includes a frame to support the reservoirs and to fit inside the insulated cabinet 106. The cart may further include a heating element and temperature sensor, configured to supply heat to a fluid in the reservoirs and sense the temperature of a fluid in the reservoir, respectively. The cart may be configured to store thermal masses, such as ice packs, adjacent to the reservoirs 106. A pump may be disposed on the cart, and configured to apply a pressure to the fluids in the reservoirs 106. The reservoir cart 204 may be wheeled up the ramp 202, and the reservoirs 106 are connected to the fluid tubing in order to provide a flow path from the reservoir to the spigot of the shelter. The connections may be quick-disconnects connections similar to the connector pair 210 described in FIG. 2C.

FIG. 2C depicts a fluid and electrical connector pair, in accordance with an embodiment. In particular, FIG. 2C depicts a cross sectional view of the fluid and electrical connector pair 210. The connector pair 210 may be used to join sections of the fluid tubing between the fluid reservoirs and the spigot. As shown in FIG. 2C, the left half of the connector pair includes electrical connections 212A and fluid connections 214A within the housing 218A. The right half of the connector pair includes electrical connections 214B and fluid connections within the housing 218B, and further includes a flange 220 to mount the right half of the connector pair to a fixture of the portable shelter. Each of the respective connections are configured to mate when the left half of the connector pair is engaged with the right half of the connector pair. The engagement of the two connector pairs may be via a twist-to-lock configuration. The wires leading to the electrical connections 212A and tubing leading to the fluid connections 214A may be combined within a sheath 216 to keep the wires and tubing contained and provide strain relief at the housing.

In some embodiments, the reservoirs 106 include fluid-temperature sensors and level detectors. Electrical signals from the fluid-temperature sensors and level detectors may be conveyed through the electrical connections 212A-B of the connector pair 210.

FIG. 3 depicts a shelter including a solar panel, in accordance with an embodiment. In particular, FIG. 3 depicts the shelter 300. The shelter 300 may include many of the same components as the shelters 100 and 200, and further include a solar panel 302, an electric eye 304, and an insulated hot beverage container 306.

In some embodiments, the shelter includes an electrical power distribution system configured to supply electrical power to the control panel. The electrical power distribution system may further include a rechargeable battery. The rechargeable battery may be disposed in the insulated cabinet.

In some embodiments, the electrical distribution system includes the solar panel 302. The solar panel 302 is configured to receive sunlight and convert the sunlight into an electrical charge capable of powering electrical devices. The electrical power distribution system may be configured to convey the electrical power from the solar panel to either one or both of the control panel and the battery.

In some embodiments with a solar panel, the shelter further includes the electric eye 304. The electric eye 304 is configured to detect a position of a light source, and the solar panel 302 is configured to be repositioned in response to a signal from the electric eye 304 that indicates the light source position. The solar panel 302 may be repositioned by rotating, tilting, or both.

In accordance with an embodiment, the shelter is further configured with a solar charging device, the solar charging device configured to charge the batteries of the shelter. The solar charging device may further include a mounting bracket for holding the solar panel 302, and including an axial support whose angle may be adjusted according to the latitude of the location where the device is to be used such that the mounting bracket can pivot and generally track the movement of the sun. The bracket may also include a directional light sensor, such as the electronic eye 304, that is used to provide feedback to control an actuator configured to automatically reposition the mounting bracket to track a light source.

In some embodiments, the shelter further includes the insulated hot beverage container 306. The insulated hot beverage container 306 is similar to the insulated container 110 of the shelters 100 and 200, but is configured to store reservoirs that contain fluid at a high temperature relative to the temperature of the fluids in the reservoirs within the insulated container 110. The fluids from the reservoirs within the insulated hot beverage container 306 are conveyed to the spigot via fluid tubing.

In some embodiments, the shelter includes an identity-verification device configured to detect an identity of a user. The identity detection may be through detecting a Radio Frequency Identification (RFID) tag, NFC data, a user entering a PIN or password, scanning a barcode, or the like.

In some embodiments, the control panel is further configured to provide an electrical charge, via an electronic device charging station, to portable electronic devices. The electrical charge may be conveyed to various wired and wireless charging capabilities, as known by those with skill in the art. The electrical charge may be provided only after the identity-verification device associated a user with an authorized user.

In some embodiments, the fluid delivery system further includes a flow meter configured to detect a volume of fluid dispensed and communicate the detected volume to the control panel. The control panel may transmit data through a wired or wireless connection to a remote server for use in monitoring data associated with capacity and fullness of the reservoirs.

In some embodiments, the insulated cabinet is configured to house a plurality of reservoirs. Each reservoir in the plurality of reservoirs may be connected to the spigot through different flow paths, and the control panel is configured to dispense fluid from a selected reservoir through the spigot. Each of the different flow paths may include fluid tubing from the respective reservoir to the spigot and further include check valves in the flow path to prevent backflow into an alternate reservoir. The separate flow paths may have their own individual pumps to convey the fluid from each respective reservoir to the spigot.

In some embodiments, the shelter further includes a beverage opener. The beverage opener may be a beer bottle opener and further include a bottle-top catch positioned under the beer bottle opener to collect the bottle tops. The beverage opener may be a wine bottle opener.

In some embodiments, the shelter further includes a thermo-electric cooling element configured to transfer heat from a liquid contained in the reservoir. The thermo-electric cooling element may be a peltier tile that receives electrical power from the electrical power distribution system. Heat may be transferred from the peltier tile to the outside environment with the assistance of heat sinks and fans.

In some embodiments, the umbrella is configured to be operated by an electric motor. The operations of the umbrella include transitioning the umbrella canopy from an open to a closed position, and back to an open position. The operations of the umbrella canopy may be per a schedule, per a remote control, in response to a weather module detecting high-wind conditions, or initiated via the control panel.

In some embodiments, the shelter includes an infrared detector configured to detect the presence of a human under the umbrella canopy. The canopy motor may be prevented from closing the umbrella canopy in response to the infrared detector detecting the presence of a person under the umbrella. In another embodiment, the shelter may further comprise a motion sensor to detect motion in the vicinity of the umbrella canopy. The canopy motor receives an input from the motion detector when motion is detected under the canopy. In response to the received input, the canopy motor stop movement of the canopy.

In some embodiments, the shelter includes an entertainment system comprising an audio speaker configured to play sound. The source of the sound may be received via wired or wireless connections, such as, RCA Cable, Audio Cables, Bluetooth, or Wi-Fi.

In accordance with an embodiment, the shelter comprises an electric eye, a solar panel, a solar rotation motor and support housing, a solar panel support arm, a wind and environmental temperature sensor configured to measure the temperature in the area around the shelter, a motor configured to deploy a canopy, a motor/canopy deployment housing, a cantilevered umbrella, lighting, an insulated cabinet housing, a tray, a ramp, a door, a speaker, a power supply, a reservoir, a rolling reservoir cart, a reservoir, a cup dispenser, and a climate control device.

In some embodiments, the solar panel collects solar energy and converts the solar energy to electricity. The electricity is utilized to power various electrical loads associated with the shelter, to include the shelter's batteries, pumps, charging connections, lights, and control panel. The solar panel may further comprise an electric eye. The electric eye is configured to detect the position of the sun, and in conjunction with the motor and support arm, reposition the solar panel in response to input from the electric eye. The solar panel is capable of being removed from the shelter via the quick release rotating mount. The solar panel is electrically connected via a wiring system to the solar panel electrical distribution system, as known by those with skill in the art.

In accordance with an embodiment, the charging connections may be located in a secure portion of the shelter. In one embodiment, the secure portion is a locker configured to fit a personal electronic device and lock and unlock in response to a user input and an identity verification, respectively.

The wind and temperature sensor is configured to detect the weather conditions surrounding the shelter. The sensor may comprise either a wind sensor, a temperature sensor, or both a wind and temperature sensor. The sensor is configured to detect weather conditions. The detected weather conditions are communicated with the shelter to support operation of the shelter. In one embodiment, the sensor detects a high wind condition and directs the canopy motor, either directly or indirectly, to close the umbrella canopy. The detected weather conditions may also be communicated, by a network interface, to a remote server.

The cantilevered umbrella is mechanically connected to the insulated reservoir, the reservoir acting as a base for the umbrella. The insulated container comprises a power supply. It may further comprise the reservoir, speakers, fluid dispensing tubing, a spigot, and a tray. The reservoir is connected to the tubing to provide a flow path to the spigot. The insulated container is configured to insulate the reservoir and other components of the insulated container may or may not be insulated. For example, the power supply may be located in the insulated container, but not insulated. The reservoir may be a single reservoir or a plurality of reservoirs. The reservoir is configured to be loaded on a cart, the cart configured to deliver the reservoir to the insulated cabinet. Delivering the reservoir to the cabinet may comprise rolling the cart up a ramp which aligns the reservoir to connect to the tubing, and any electrical connections, associated with the shelter.

The power supply may be a battery, a rechargeable battery, or the like.

The speaker may comprise a waterproof speaker, and the speaker may be configured to receive audio data via Bluetooth, a wireless connection, or a wired connection.

The shelter may further comprise a climate control. The climate control comprises fans powered by the power supply, misters receiving fluid from a reservoir, or both fans and misters.

In accordance with an embodiment, the canopy of the umbrella further comprises a canopy extension. The canopy extension is additional canopy material that affixes to the canopy and another stationary object, such as a tree, stake, railing, or the like.

In accordance with an embodiment the insulated container includes the tray, the speaker, a stereo, and the spigot. The tray is located under the spigot and is configured to catch excess runoff of fluid dispensed from the spigot. The stereo is configured to receive and play audio signals via the speakers. The received audio may be received wirelessly or via a wired connection. Example wireless methods include Bluetooth, Wi-Fi, and the like. Example wired connections include a USB or audio cable connected to a portable electronic music player, such as a smartphone or an MP3 player. The stereo receives electrical power from the power supply.

In accordance with an embodiment, a cart is used to transport and connect beverages to an insulated cabinet of a shelter, in accordance with an embodiment. The cart may be a rolling cart, having the reservoir, a thermal mass or ice pack, a solenoid valve, a flow sensor, a pump, a float valve, a housing, a self-sealing quick-disconnect, an electric and fluid connection point, a wheeled cart frame, a temperature sensor and a heating element.

In accordance with such an embodiment, the rolling cart is configured to (i) store the reservoir and (ii) fit within the housing. The shelter may be further configured to regulate temperature of liquid in the reservoirs. The regulation comprises a temperature sensor configured to detect temperature of liquid in the reservoir and communicate the detected temperature to a controller. The regulation further comprises a heating element which may be configured to activate responsive to a detected temperature from the temperature sensor. The regulation may further comprise use of a thermal mass such as an ice pack, a thermo-electric cooling system or other condenser-type cooling system.

In accordance with an embodiment, the shelter may further comprise a cooling element, the cooling element disposed in the insulated cabinet and configured to cool the liquid stored in the reservoir. The cooling element may be a thermoelectric tile powered from the shelter's distribution system or a standard cooling compressor. The cooling element may provide cooling to the liquid in the reservoir instead of or in conjunction with ice packs. The cooling element may further be configured to provide cooling in response to input from a temperature sensor.

The electric and fluid connection point is configured to receive fluid from the reservoirs and electrical power from the battery and convey the fluid and power to the shelter. The connection point may be further configured to communicate control signals and other electronic data, such as audio data, wind data, charging data, and the like.

In accordance with an embodiment, the reservoir is a plurality of reservoirs, wherein one of the plurality of reservoirs is configured to be filled via an external fluid source, such as a hose. The one of the plurality of reservoirs further comprises a water filter. The plurality of reservoirs may also be achieved by dividing a single reservoir into two chambers.

The fluid dispensing functions of the shelter may be carried out by the reservoir, the solenoid valve, the flow sensor, the pump, the float valve, and interconnecting tubing. The solenoid valve may be configured to open and shut to establish a flow path between the reservoir and the spigot. The pump, powered by the power supply or manual operation, provides the fluid pressure to move the liquid. The pump may be a positive displacement pump or a centrifugal pump. The flow sensor is configured to determine the quantity of liquid dispensed.

In accordance with an embodiment the insulated container includes the spigot, a grate, and a user interface element. The user interface element is configured to receive user inputs and communicate the user inputs to the functions of the shelter. Example user inputs include dispensing liquid, playing audio, deploying the umbrella, retracting the umbrella, activating electrical charging, operation of the climate control features, system administrator functions and the like.

In accordance with an embodiment, the insulated cabinet includes the solenoid valve, the flow sensor, a multi-connection manifold, an umbrella controller, a controller, a user interface, a momentary button, a NFC reader, a lock, a remote receiver, the spigot, and a remote.

The umbrella controller is electrically connected with the controller to reposition the umbrella between an open and a closed position. The controller acts responsively to a user input, an adverse weather detection, or a pre-determined schedule. For example, the controller may open or close the umbrella based on a user's interaction with the user interface, upon detecting a high wind condition—either through built in wind detectors or a weather forecast—or may open at the start of a business day and close at the end of the business day.

The NFC reader is part of an identification system. The NFC reader is configured to detect an NFC chip associated with an individual and communicate the detection of the NFC chip to the computer processing system associated with the control panel. The NFC chip can also be substituted with other devices to implement other methods of identity verification. These methods may include a card reader scanning a magnetic strip on a hotel key card, a user entering a password via a user interface, scanning of a bar code or a QR code, or the like.

The solenoid valves are configured to control access to beverages dispensed by the fluid dispensing system. The fluid dispensing system also comprises a splitter manifold to connect multiple beverages, momentary waterproof buttons, and a faucet. The solenoid valves may actuate, and permit fluid to flow through the fluid dispensing system in response to an actuation of a momentary button and the results of an identification verification.

The speaker may comprise a waterproof Bluetooth speaker and be configured to receive control signals from the speaker remote. The speaker remote communicates with the speaker through a wired or wireless connection and is capable of communication control signals, such as volume changes, play controls, input selections, and the like.

The lock may comprise an electronic lock and prevent access to the insulated cabinet.

In accordance with an embodiment, the shelter further includes a fan-mist attachment. Components of the fan-mist attachment may include an air compressor, a fan adjustment device, a reservoir, a flow adjustor valve, and a fan controller. In various embodiments, the pressure to move fluid from the reservoir is generated by the air compressor pressurizing air above the fluid in the reservoir. The air pressure provides the pressure to move the fluid to either the spigot or the mister. Alternatively, the pump can be used to move fluid. The fans, pumps, and air compressors are capable of being adjusted to provide varying fluid flows and air pressures.

In accordance with an embodiment the shelter may include a weather module. The weather module may include wind and temperature modules configured to prevent damage to the umbrella by detecting high wind conditions and either preventing the umbrella from opening during high wind conditions or automatically controlling the closing of the umbrella once high winds are detected. The detected weather conditions can control the operation of the umbrella motor either directly or indirectly through the control panel.

The shelter may further include cleaning and flushing connections to permit the reservoirs to be flushed, with fluid from an external source. The external source may be water from a hose connected to the reservoirs. The tubing connections may be further configured to cycle a cleaning fluid in a closed loop system to sanitize the internal components of the fluid delivery system.

In one example use case, the shelter detects a condition that requires a user to correct. Such a condition may be a level of a fluid is below a threshold level, a temperature of the fluid is outside of an acceptable temperature band, a set period of time has elapsed since the shelter has last been serviced or the like. The detected condition triggers the shelter to transmit a notification, via a network interface. An employee at a business associated with the shelter receives a notification indicating that the shelter requires attention and the nature of the detected condition. In this example use case, the employee is required to bring a full fluid reservoir to the station to correct a low fluid level condition. The employee loads a full reservoir onto a reservoir cart, transports the reservoir cart to the shelter, opens the door on the insulated cabinet, removes the reservoir associated with the low level condition, disconnects the low level reservoir and connects the full reservoir to the shelter. The employee then shuts the door, resets any conditions necessary on the shelter to enable fluid to be conveyed from the full reservoir to the spigot, and returns the empty reservoir to storage.

FIG. 4 depicts a schematic functional block diagram of a computer processing system, in accordance with an embodiment. In particular, FIG. 4 depicts a schematic functional block diagram of an exemplary computer processing system in accordance with some embodiments. A computer processing system, such as the exemplary computer processing system depicted in FIG. 4, may be used to control portions and functions of shelter, to include, but not be limited to operations of the control panel, the fluid delivery system such as pumps and solenoid valves, transmission of data to remote servers, operations of the solar charging system, and the like. The computer processing used may be a generic computer processing system capable of carrying out the disclosures of this invention. Example computer processing systems include smart phones, phones, laptops, computers, car navigation systems, RF remotes and the like. The computer processing systems may be connected to remote and local networks or other remote computer processing systems. The functions described as being carried out in one computer processing system may also be carried out in a remotely connected computer processing system, as known by those with skill in the relevant art. It may be appreciated that the methods of this disclosure are completed on multiple computer processing systems which are communicatively coupled together.

In some embodiments, the systems and methods described herein may be implemented in a computer processing system, such as the computer processing system 1902 illustrated in FIG. As shown in FIG. 4, the computer processing system 1902 may include a processor 1918, a network interface 1920, a user interface 1926, a display 1928, a non-removable memory 1930, a removable memory 1932, a power source 1934, and other peripherals 1938. It will be appreciated that the server 1902 may include any sub-combination of the foregoing elements while remaining consistent with an embodiment. The server may be in communication with the internet and/or with proprietary networks.

The computer processing system 1902 can incorporate the embodiments of this disclosure. For example, the peripherals 1938 may include the internal sensor, the external sensor, and any optional auxiliary sensors. The display 1928 may include the virtual reality display, and any optional audio speakers. The network interface may include the communication interface.

The processor 1918 may be a general purpose processor, a special purpose processor, a conventional processor, a digital signal processor (DSP), a plurality of microprocessors, one or more microprocessors in association with a DSP core, a controller, a microcontroller, Application Specific Integrated Circuits (ASICs), Field Programmable Gate Array (FPGAs) circuits, any other type of integrated circuit (IC), a state machine, and the like. The processor 1918 may perform signal coding, data processing, power control, input/output processing, and/or any other functionality that enables the server 1902 to operate in a wired or wireless environment. The processor 1918 may be coupled to the network interface 1920. While FIG. 7 depicts the processor 1918 and the network interface 1920 as separate components, it will be appreciated that the processor 1918 and the network interface 1920 may be integrated together in an electronic package or chip.

The processor 1918 of the server 1902 may be coupled to, and may receive user input data from, the user interface 1926, and/or the display 1928 (e.g., a liquid crystal display (LCD) display unit or organic light-emitting diode (OLED) display unit). The processor 1918 may also output user data to the display/touchpad 1928. In addition, the processor 1918 may access information from, and store data in, any type of suitable memory, such as the non-removable memory 1930 and/or the removable memory 1932. The non-removable memory 1930 may include random-access memory (RAM), read-only memory (ROM), a hard disk, or any other type of memory storage device. In other embodiments, the processor 1918 may access information from, and store data in, memory that is not physically located at the server 1902, such as on a separate server (not shown).

The processor 1918 may receive power from the power source 1934, and may be configured to distribute and/or control the power to the other components in the server 1902. The power source 1934 may be any suitable device for powering the server 1902, such as a power supply connectable to a power outlet.

Although features and elements are described above in particular combinations, one of ordinary skill in the art will appreciate that each feature or element can be used alone or in any combination with the other features and elements. In addition, the methods described herein may be implemented in a computer program, software, or firmware incorporated in a computer-readable medium for execution by a computer or processor. Examples of computer-readable storage media include, but are not limited to, a read only memory (ROM), a random access memory (RAM), a register, cache memory, semiconductor memory devices, magnetic media such as internal hard disks and removable disks, magneto-optical media, and optical media such as CD-ROM disks, and digital versatile disks (DVDs). A processor in association with software may be used to implement a radio frequency transceiver for use in a WTRU, UE, terminal, base station, RNC, or any host computer. 

1. A shelter comprising: an umbrella supported by a base, an insulated cabinet attached to the base, the insulated cabinet having a door, and defining a fluid-reservoir receiving means; a fluid delivery system comprising a reservoir, a pump, a spigot disposed on an upper portion of the insulated cabinet, and fluid tubing; and a control panel disposed on the insulated cabinet and having a user-interface input, the control panel configured to activate a fluid-conveyance means to convey a fluid from the reservoir, via the fluid tubing, to the spigot in response to receiving a fluid-dispense request at the user-interface input.
 2. The shelter of claim 1, wherein the fluid-reservoir receiving means comprises a ramp configured to receive a reservoir cart, the reservoir cart loaded with a fluid reservoir.
 3. The shelter of claim 1, wherein the fluid-reservoir receiving means comprises installing the reservoir into a cavity of the insulated cabinet accessible through the door.
 4. The shelter of claim 1, further comprising an electrical power distribution system configured to supply electrical power to the control panel.
 5. The shelter of claim 4, wherein the electrical power distribution system comprises a rechargeable battery to provide electrical power disposed inside the insulated cabinet.
 6. The shelter of claim 5, wherein: the electrical power distribution system further comprises a solar panel on a mount; and the electrical power distribution system is further configured to convey electrical power from the solar panel to either one or both of the control panel and the rechargeable battery.
 7. The shelter of claim 6, wherein: the solar panel further comprises a directional light sensor configured to detect a position of a light source; and an actuator is configured to reposition the bracket in response to a feedback signal from the directional light sensor.
 8. The shelter of claim 1, further comprising an upright support pole configured attached to the base, the umbrella is cantilevered in a first direction from the upright support pole and the insulated cabinet is positioned in a second direction from the upright support pole, the second direction opposing the first direction.
 9. The shelter of claim 1, wherein the control panel further comprises an electronic device charging station.
 10. The shelter of claim 9, wherein the control panel is further configured to provide an electrical charge, via the electronic device charging station to an electronic device, in response to a signal from an identity-verification device.
 11. The shelter of claim 4, further comprising lights affixed to the underside of a canopy of the umbrella, wherein the electrical power distribution system is further configured to supply electrical power to the lights.
 12. The shelter of claim 1, wherein the fluid delivery system further comprises a flow meter configured to detect a volume of fluid dispensed and communicate the detected volume to the control panel.
 13. The shelter of claim 1, wherein the fluid-conveyance means comprises a plurality of reservoirs, and the fluid-conveyance means is further configured to dispense a liquid from a selected one of the plurality of containers through the spigot.
 14. The shelter of claim 1, further comprising a beverage opener.
 15. The shelter of claim 14, wherein the beverage opener is selected from a group consisting of a beer bottle opener and a wine bottle opener.
 16. The shelter of claim 1, further comprising a thermo-electric cooling element configured to transfer heat from a liquid contained in the reservoir.
 17. The shelter of claim 1, wherein the umbrella is configured to be operated by an electric motor.
 18. The shelter of claim 17, wherein the umbrella is further configured to be operated to a closed position in response to an infra-red detector not detecting a person under the umbrella.
 19. The shelter of claim 1, further comprising an entertainment system comprising an audio speaker configured to play sound.
 20. The shelter of claim 19, wherein the shelter is further configured to wirelessly receive data and the speaker is further configured to play sound based on the received data. 